KR20220169045A - Autonomous driving quarantine robot injecting ozonated water or ionized water when detecting contamination by germs - Google Patents

Abstract

The present invention relates to an autonomous driving quarantine robot for injecting ozone water. The purpose of the present invention is to remove a disadvantage of a disinfection robot using an ultraviolet lamp and the disinfection robot injecting disinfection solution. To this end, the present invention comprises: a driving wheel (50); a main body provided to an upper portion of the driving wheel (50); and an injection nozzle (90) provided on a side surface of the main body. The injection nozzle (90) injects the ozone water ozonizing tap water.

Description

Autonomous driving quarantine robot that detects contamination and sprays ozone water or ionized water

The present invention relates to an autonomous quarantine robot that automatically sprays ozonated water or ionized water when air pollution is detected. The present invention relates to a self-driving quarantine robot capable of autonomously performing disinfection by automatically spraying ozone water or ionized water when a pathogen is detected.

The importance of disinfection and quarantine is being emphasized in accordance with the recent global spread of COVID-19.

In addition, in recent years, cases of infection with various bacteria or viruses (hereinafter collectively referred to as 'pathogens') in hospitals are increasing.

When a pathogen infection occurs in a hospital, quality of medical care may be deteriorated, treatment of a patient may be delayed, and problems such as passive response of medical personnel to patients may be caused.

Therefore, in places such as hospitals where the spread of pathogens is a concern, disinfection is conducted regularly according to a set standard.

The most common disinfection method is that a person holds a sprayer and sprays disinfectant water around the object to be disinfected.

However, the manual disinfection method as described above has disadvantages in that the disinfectant agent may leak to a person and threaten health, and since a person directly performs the disinfection operation, a large number of manpower is required.

On the other hand, in an enclosed space such as a sterile room, there is also a method of disinfection by injecting ultraviolet rays or infrared rays to an object to be disinfected.

However, this method has disadvantages in that a sterile room must be separately installed, and the work of moving and carrying out the disinfection object to and from the sterile room is cumbersome.

In order to solve this problem, a method using a robot without a person directly disinfecting has been proposed.

An example of this is Korean Patent Registration No. 10-1742489 entitled "Ultraviolet Sterilization Mobile Robot Apparatus and System".

As shown in FIG. 1, the conventional ultraviolet sterilization mobile robot 100 as described above includes a main body 180 having an upper portion capable of being opened and closed; a sensor unit 120 formed on an outer circumferential surface of the main body 180 to detect an external topography and a distance to an external object; An ultraviolet sterilization unit 150 formed inside the body 180 and exposed to the outside when the upper portion of the body is opened to irradiate ultraviolet rays; A transfer unit formed on the bottom surface of the main body and moving along the movement path; and a control unit 140 that controls the moving path of the transfer unit using data detected by the sensor unit 120 and controls ultraviolet sterilization of the ultraviolet sterilization unit 150.

In addition, the main body 180 includes a display unit 160 and a power supply unit 130, and a communication unit 110 and a power charging unit 170 are provided in the lower portion of the body.

Here, as for the ultraviolet rays, UVC having a wavelength of 280 to 100 nm is mainly used.

According to the ultraviolet sterilization mobile robot described above, by providing an ultraviolet sterilization lamp 151 inside the mobile robot, germs such as bacteria and viruses can be removed with ultraviolet rays, and the user can be prevented from being exposed to disinfectants. there is

In this way, it is possible to effectively prevent pathogen infection in the hospital.

However, the ultraviolet sterilization robot described above has limitations in its sterilization effect because it uses an ultraviolet lamp. In particular, there is a problem in that it is difficult to intensively sterilize a specific area or surface.

In addition, a method of spraying a disinfectant using a robot has been proposed, and FIG. 2 shows an example thereof.

The conventional robot shown in FIG. 2 is an autonomous disinfection robot spraying a disinfectant solution, including an autonomous disinfection robot 200 capable of self-driving while spraying a humidifier or disinfectant solution unattended; It includes a server 210 that receives data about spray control of a humidifier or disinfectant solution and autonomous driving of the robot from the robot, and a user terminal 220 that receives data transmitted from the server 200, and the server receives a control signal received from the user terminal and transmits it to the robot so that the robot performs a predetermined control operation according to the control signal.

According to the self-driving disinfection robot of the above-described method, unattended spraying is possible, which has the advantage of preventing the user from being exposed to the disinfectant.

In addition, since the disinfection robot can be monitored through the application of the user terminal, there is an advantage in that flexible control is possible according to the state of the disinfection robot.

However, the above-described disinfection robot has a problem in that an expensive disinfection solution must be continuously purchased.

Sodium hypochlorite is mainly used as the disinfectant solution, and the disinfectant solution is currently sold at about 145,000 won to 550,000 per 20 liters, giving an economic burden.

As a result, even though disinfection is urgently needed, disinfection robots are not widely distributed.

In addition, since the above disinfection solution spraying method leaves stains caused by chemical components on the object to be disinfected, there is a problem that the stains on the object to be disinfected must be wiped off one by one after the disinfection solution is sprayed.

As a result, it is pointed out that the labor cost for cleaning the stain is additionally required, and the advantage of the autonomous robot cannot be utilized.

Korean Patent Registration No. 10-1742489 (Announced on June 2, 2017) Korean Patent Registration No. 10-1724481 (Announced on April 11, 2017) Korean Patent Publication No. 10-2019-0065569 (published on June 12, 2019)

The present invention is to solve the problems of the prior art, and an object of the present invention is to solve the disadvantages of a disinfection robot that sprays ultraviolet rays and a disinfection robot that sprays disinfectants.

Another object of the present invention is to disinfect a space that is difficult to be disinfected by an ultraviolet lamp type disinfection robot.

Another object of the present invention is to reduce the maintenance cost of the disinfection robot as much as possible while increasing the disinfection efficiency.

Another object of the present invention is to prevent stains on the object to be disinfected after spraying the disinfectant solution.

Another object of the present invention is to spread the spread of quarantine robots by minimizing the maintenance cost of disinfection robots.

Another object of the present invention is to enable a disinfection robot to perform the function of a cleaning robot as well.

In order to achieve the above object, the present invention is an autonomous quarantine robot comprising a driving wheel, a main body provided on the upper part of the driving wheel, and a spray nozzle provided on the side of the main body, waiting for the main body. A detection sensor for detecting the contamination state is provided, and when the detection sensor detects the contamination state, the injection nozzle sprays ozone water obtained by ozonizing tap water or ionized water obtained by ionizing tap water to perform quarantine and disinfection. .

In addition, the detection sensor is characterized in that it comprises a pathogen detection sensor for detecting pathogens.

In addition, an oxygen supply device and an ozone generator are built into the main body to generate ozonated water on its own.

In addition, an ozone water generating device is built into the main body to generate ionized water on its own.

In addition, it is characterized in that a camera and a touch screen are provided on the outside of the main body.

In addition, the camera is characterized in that it consists of a CCD type camera or a CMOS type camera.

In addition, a control unit for controlling the driving of the quarantine robot is provided inside the main body, and the control unit is characterized in that it includes a main computer and a main PCB.

In addition, it is characterized in that the control unit is controlled by a remote controller.

In addition, it further includes a server that receives autonomous driving data of the quarantine robot, and a user terminal that receives data transmitted from the server, and transmits a signal transmitted from the user terminal to the quarantine robot.

In addition, a cleaning module is further provided at the bottom of the main body to perform disinfection and cleaning at the same time.

In addition, the cleaning module is characterized in that it is configured to include a brush motor for rotating the brush and a suction motor for sucking dirt.

In addition, when the quarantine robot is operating, it is characterized in that it informs that quarantine is in progress by means of a speaker or a warning light.

According to the present invention, since it is a method of disinfection using ozonated tap water or ionized tap water, there is an effect of not having to purchase an expensive disinfectant solution.

In addition, there is an effect of significantly reducing the maintenance cost of quarantine robots and spreading the spread of quarantine robots.

In addition, since it is a method of spraying ozonated water or ionized water by a spray nozzle, there is an effect of disinfecting a space that is difficult to be sterilized by an ultraviolet lamp type disinfection robot.

In addition, since the object to be disinfected is not stained by the disinfectant after the quarantine operation, there is an effect that a person does not have to clean the object to be disinfected again.

In addition, since the quarantine robot serves as a cleaning robot, there is an effect of simultaneously performing quarantine and cleaning work.

1 is a view showing a disinfection robot of a UV lamp method according to the prior art.
Figure 2 is a view showing a disinfection robot of the disinfection solution spray method according to the prior art.
3 is a view showing an autonomous driving disinfection robot spraying ozone water or ionized water according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

<First Embodiment>

As shown in FIG. 3, the self-driving quarantine robot according to the first embodiment of the present invention includes a driving wheel 50, a main body provided on top of the driving wheel 50, and a side surface of the main body. In the self-driving disinfection robot comprising a spray nozzle 90, a sensor for detecting air pollution is provided in the main body.

In addition, when the detection sensor detects a contamination state, the spray nozzle 90 sprays ozone water obtained by ozonizing tap water or ionized water obtained by ionizing tap water to perform quarantine and disinfection.

The ozonated water used in the present invention uses liquid ozonated water that is a mixture of ozone and tap water.

The ozone is effective in sterilization and odor removal due to its strong oxidizing power, and also serves as a protective film by forming an ozone layer in the atmosphere.

Here, the ozonated water may be generated by an ozonated water generating device built into the main body or may be generated by a separate ozonated water generating device and supplied to the quarantine robot.

The ozone water generating device includes an oxygen supply device for supplying high-concentration oxygen and an ozone generator for generating gaseous ozone by decomposing oxygen.

Since the ozone water generator itself is a known technology, a detailed description thereof will be omitted.

And the drive wheel 50 is provided on the lower part of the main body and is driven by the motor drive unit 60 .

In addition, the motor driving unit 60 is driven by the battery 40, and the battery may be composed of a lithium ion battery.

And the spray nozzle 90 sprays the ozone water toward the object to be disinfected.

In addition, a camera 10 and a touch screen 20 are provided outside the main body.

The camera 10 plays a role in detecting an obstacle so that the self-driving disinfection robot moves smoothly.

The camera 10 may be configured as a CCD (Charge-Coupled Device) type camera or a CMOS (Complementary Metal Oxide Semiconductor) type camera.

The CCD type camera converts an image into an electrical signal using a charge-coupled device (CCD) and transmits it to the control unit.

In addition, the CMOS type camera uses an imaging device having a complementary metal oxide semiconductor (CMOS) structure, and has an advantage in that power consumption is lower than that of the CCD type camera.

Also, the camera may include a laser sensor.

And the touch screen 20 is configured so that the user can manually operate the quarantine robot.

In addition, in the present invention, various sensors 70 are provided on the outside of the main body.

The sensor 70 may further include any one or a combination of a motion sensor, an infrared sensor, an ultrasonic sensor, and an optical sensor, as well as a pathogen detection sensor for detecting various pathogens.

When a pathogen is detected by the pathogen detection sensor, the self-driving quarantine robot automatically starts driving and sprays ozone water or ionized water.

In addition, in the present invention, it is preferable to provide a speaker to the main body so as to inform people around the operation status of the quarantine robot.

In other words, when quarantine starts, the message "I will start quarantine" can be output, and when quarantine is performed while autonomously driving, the message "quarantine is in progress" can be output.

In addition, when the quarantine work is in progress while the robot is running, it is desirable to turn on the warning light together.

This allows people around them to recognize that the air is polluted and quarantine and disinfection is in progress.

In addition, the present invention includes a control unit for controlling the driving of the disinfection robot inside the main body.

The controller includes a main computer 30 and a main PCB 80, and controls the quarantine robot as a whole by processing signals, data, information, etc. input to each component.

In other words, it controls functions such as detection of pathogens, start of quarantine, autonomous driving, stop of quarantine, and battery management.

Meanwhile, a user may control the controller by a remote controller.

In addition, the present invention may connect a server that receives autonomous driving data of a quarantine robot and a user terminal that receives data transmitted from the server through wireless Internet communication.

In this case, the user terminal may include a sensing unit, an input unit, an output unit, a wireless communication unit, an interface unit, a memory unit, and the like.

In addition, Deep Learning technology can be applied to the quarantine robot of the present invention.

The deep learning is a field of machine learning, and is a technology that allows a program to make similar judgments for various situations, rather than a method of checking conditions and setting commands in advance in a program.

With the deep learning, a computer can think similarly to the human brain and analyze a vast amount of data.

An autonomous robot itself that disinfects or cleans while avoiding obstacles is known.

However, among conventional disinfection robots, a robot that scans ultraviolet rays has a limited sterilization effect, and it is difficult to sterilize a specific area intensively.

In addition, the robot spraying the disinfectant is expensive, and there is a burden of continuously purchasing an expensive disinfectant solution costing hundreds of thousands of won for 20 liters.

As a result, even though quarantine is more important than ever, quarantine robots are not widely distributed.

In addition, the disinfectant spray robot has a problem that a person has to erase the stains one by one because stains remain on the object to be disinfected after spraying the disinfectant.

In other words, while using the self-driving robot, a person has to clean the stain again, so the advantage of using the robot cannot be taken advantage of.

On the other hand, the present invention is a method of disinfection by spraying ozonated water using tap water or ionized water obtained by ionizing tap water, so there is no need to purchase expensive disinfectants.

In addition, since the present invention is a method of spraying ozonated water or ionized water, it is possible to completely disinfect spaces that are difficult to be sterilized by an ultraviolet lamp-type disinfection robot.

In addition, since disinfection is performed using ozonated water or ionized water, stains caused by disinfectant components are not generated on the object to be disinfected during disinfection.

As a result, since there is no need to clean stains on the object to be disinfected after disinfection, labor costs can be reduced and advantages of the autonomous robot can be utilized.

In addition, since the maintenance cost of the quarantine robot can be reduced as much as possible, the distribution of the quarantine robot can be widely spread.

<Second Embodiment>

In the second embodiment of the present invention, an ionized water generating device is further provided inside the main body in the above-described first embodiment.

According to the second embodiment of the present invention, it is possible to selectively spray ozonated water and ionized water to the object to be disinfected. Here, the ionized water may be obtained by electrolyzing tap water using an ionized water generator.

Since the ionized water generator itself is a known technology, a detailed description thereof will be omitted.

Since other matters are the same as those of the first embodiment described above, duplicate descriptions will be omitted.

<Third Embodiment>

A third embodiment of the present invention further includes a cleaning module on the bottom of the main body in the above-described first embodiment. In other words, the function of a well-known cleaning robot is added to the quarantine robot.

The cleaning module according to the third embodiment of the present invention may include a brush motor and a suction motor.

The brush motor rotates the brush, and the suction motor serves to suck dust or dirt from the floor.

According to the third embodiment of the present invention, it is possible to perform disinfection work and cleaning work simultaneously by one quarantine robot.

Other matters are the same as those of the first embodiment described above.

In the above, preferred embodiments of the present invention have been described by way of example, and the scope of the present invention is not limited to the above specific embodiments. Those skilled in the art to which the present invention pertains will understand that various modifications and changes are possible without departing from the scope of the technical spirit of the present invention.

10: Camera 20: Touch Screen
30: Main Computer 40: Battery
50: driving wheel (Wheel) 60: motor driving unit
70: Pathogen detection sensor 80: Main PCB (PCB)
90: spray nozzle (Nozzle)

Claims (12)

In the self-driving disinfection robot including a driving wheel 50, a main body provided on the upper part of the driving wheel 50, and a spray nozzle 90 provided on the side of the main body,
The main body is provided with a sensor for detecting air pollution,
When the detection sensor detects a contamination state, the spray nozzle 90 sprays ozone water obtained by ozonizing tap water or ionized water obtained by ionizing tap water to perform quarantine and disinfection. According to claim 1,
The detection sensor includes a pathogen detection sensor 70 for detecting pathogens. According to claim 1,
An autonomous driving quarantine robot characterized in that an oxygen supply device and an ozone generator are built inside the main body to generate ozonated water on its own. According to claim 1,
An autonomous driving disinfection robot characterized in that an ionized water generator is built inside the main body to generate ionized water on its own. According to claim 1,
An autonomous driving quarantine robot, characterized in that a camera 10 and a touch screen 20 are provided outside the main body. According to claim 5,
The autonomous driving quarantine robot, characterized in that the camera 10 is made of a CCD type camera or a CMOS type camera. According to claim 1,
Inside the main body, a control unit for controlling the driving of the quarantine robot is provided,
The control unit is an autonomous driving quarantine robot, characterized in that it is configured to include a main computer (30) and a main PCB (80). According to claim 7,
The control unit is an autonomous driving quarantine robot, characterized in that controlled by a remote controller. According to claim 1,
Further comprising a server that receives autonomous driving data of the quarantine robot and a user terminal that receives data transmitted from the server,
The server is an autonomous driving quarantine robot, characterized in that for transmitting the signal transmitted from the user terminal to the quarantine robot. According to claim 1,
An autonomous driving quarantine robot, characterized in that a cleaning module is further provided at the bottom of the main body to perform quarantine and cleaning at the same time. According to claim 10,
The cleaning module is configured to include a brush motor for rotating a brush and a suction motor for sucking dirt. According to claim 1,
An autonomous driving quarantine robot characterized in that when the quarantine robot is operating, it informs that quarantine is in progress by means of a speaker or a warning light.

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